Control Synthesis for the Flow-Based Microfluidic Large-Scale Integration Biochips
Publication: Research - peer-review › Article in proceedings – Annual report year: 2013
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Control Synthesis for the Flow-Based Microfluidic Large-Scale Integration Biochips. / Minhass, Wajid Hassan; Pop, Paul; Madsen, Jan; Ho, Tsung-Yi.
In: Proceedings of the 18th Asia and South Pacific Design Automation Conference (ASP-DAC) 2013. 2013.Publication: Research - peer-review › Article in proceedings – Annual report year: 2013
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TY - GEN
T1 - Control Synthesis for the Flow-Based Microfluidic Large-Scale Integration Biochips
A1 - Minhass,Wajid Hassan
A1 - Pop,Paul
A1 - Madsen,Jan
A1 - Ho,Tsung-Yi
AU - Minhass,Wajid Hassan
AU - Pop,Paul
AU - Madsen,Jan
AU - Ho,Tsung-Yi
PY - 2013
Y1 - 2013
N2 - In this paper we are interested in flow-based microfluidic biochips, which are able to integrate the necessary functions for biochemical analysis on-chip. In these chips, the flow of liquid is manipulated using integrated microvalves. By combining severalmicrovalves, more complex units, such asmicropumps, mixers, and multiplexers, can be built. In this paper we propose, for the first time to our knowledge, a top-down control synthesis framework for the flow-based biochips. Starting from a given biochemical application and a biochip architecture, we synthesize the control logic that is used by the biochip controller to automatically execute the biochemical application. We also propose a control pin count minimization scheme aimed at efficiently utilizing chip area, reducing macro-assembly around the chip and enhancing chip scalability. We have evaluated our approach using both real-life applications and synthetic benchmarks.
AB - In this paper we are interested in flow-based microfluidic biochips, which are able to integrate the necessary functions for biochemical analysis on-chip. In these chips, the flow of liquid is manipulated using integrated microvalves. By combining severalmicrovalves, more complex units, such asmicropumps, mixers, and multiplexers, can be built. In this paper we propose, for the first time to our knowledge, a top-down control synthesis framework for the flow-based biochips. Starting from a given biochemical application and a biochip architecture, we synthesize the control logic that is used by the biochip controller to automatically execute the biochemical application. We also propose a control pin count minimization scheme aimed at efficiently utilizing chip area, reducing macro-assembly around the chip and enhancing chip scalability. We have evaluated our approach using both real-life applications and synthetic benchmarks.
BT - Proceedings of the 18th Asia and South Pacific Design Automation Conference (ASP-DAC) 2013
T2 - Proceedings of the 18th Asia and South Pacific Design Automation Conference (ASP-DAC) 2013
ER -